Studies show how asteroid-bashing spacecraft was 'phenomenally
successful'
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[March 02, 2023]
By Will Dunham
WASHINGTON (Reuters) - NASA's DART spacecraft slammed into the asteroid
Dimorphos at a spot between two boulders during last September's first
test of a planetary defense system, sending debris hurtling into space
and changing the rocky oblong-shaped object's path a bit more than
previously calculated.
Those were among the findings revealed by scientists on Wednesday in the
most detailed account of the U.S. space agency's proof-of-principle
mission on using a spacecraft to change a celestial object's trajectory
- employing sheer kinetic force to nudge it off course just enough to
keep Earth safe.
"The DART test was phenomenally successful. We now know that we have a
viable technique for potentially preventing an asteroid impact if one
day we had the need to," said planetary scientist Terik Daly of the
Johns Hopkins University Applied Physics Laboratory in Maryland, lead
author of one of the DART studies published in the journal Nature.
The Double Asteroid Redirection Test (DART) spacecraft collided on Sept.
26 at about 14,000 miles per hour (22,530 kph) into Dimorphos, an
asteroid about 490 feet (150 meters) in diameter, roughly 6.8 million
miles (11 million km) from Earth. Dimorphos is a moonlet of Didymos,
which is defined as a near-Earth asteroid and has a shape like a top
spinning in space with a diameter of about a half mile (780 meters).
Neither object imperils Earth.
"We were trying to change the amount of time that it took for Dimorphos
to orbit around Didymos by colliding head-on with Dimorphos," said
Northern Arizona University planetary scientist Cristina Thomas, lead
author of another of the studies published in Nature.
"The momentum of the collision and the momentum of the ejected material
both acted to decrease the amount of time it takes Dimorphos to orbit by
33 minutes. This also results in the object orbiting a little bit closer
to Didymos," Thomas said.
Prior to the impact, the orbital period was 11 hours and 55 minutes. It
now is 11 hours and 22 minutes. NASA's previous estimate, announced in
October, was an orbital change of 32 minutes. The benchmark for success
had been set as a change of at least 1 minute and 13 seconds.
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This image depicts NASA's DART
spacecraft and its two long solar panels over the spot where it
impacted asteroid Dimorphos in September 2022. The largest boulder
near the impact site is about 6.5 meters (21 feet) across. DART took
the underlying image three seconds before impact. NASA/Johns Hopkins
APL/Handout via REUTERS
The scientists gave a blow-by-blow account of how the collision
unfolded.
"First, one of the spacecraft's solar panels directly hit a large
boulder near the impact site. Next, the second solar panel grazed
another large boulder. Finally, the spacecraft bus - the box between
the solar panels - hit between these two boulders," Daly said.
"We suspect that these two boulders were destroyed. After impact,
ejecta (debris blasted into space) was launched from the surface for
a period of time," Daly added, saying satellite and telescope images
showed a large amount of such material.
The research also clarified details such as the precise location of
the impact and the angle of impact.
"People may think of the DART mission as a fairly straightforward
experiment that is similar to playing billiards in space - one solid
spacecraft impacts into one solid asteroid," Thomas said. "However,
asteroids are far more complex than just a solid rock. In fact, most
asteroids are what we think of as rubble piles."
The $330 million DART mission was seven years in development.
"We don't know of any asteroids at this time that pose a threat to
Earth, but we want to be ready for such a scenario," Daly said.
"It's analogous to testing a car's airbags. You make sure they work
during a crash test instead of waiting to get in a real car accident
to find out if they work."
(Reporting by Will Dunham, Editing by Rosalba O'Brien)
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